Adjustable vacuum food storage container

ABSTRACT

The invention is to provide an adjustable vacuum food storage container, comprising of a base, a socket mounted on the base, and a cover covering the socket; a vacuum controller, a pressure detective means, an out connector power means, a spare battery set, and a power switch are disposed on the base, and an exhaust valve are further added on upper cover; the pressure detective connected to the socket for auto-detecting the accommodation between the socket and the upper cover, and the vacuum controller combined to the pressure detective means for keep it at vacuum state at any moment.

FIELD OF THE INVENTION

The invention relates to a food storage container, and more particularly to an adjustable vacuum food storage container, to detect, adjust and maintain the vacuum state always.

BACKGROUND OF THE INVENTION

The demand for vacuum storing means has increased in recently years as consumers become more aware of conserving leftovers suitably rather than treating them as waste. The prior art related to make a vacuum state is prolific. Besides, it is also hard to detect whether the vacuum state is moderated, although the conventional devices can help the container to seal and reach the vacuum state at that moment, there could be a few air remnant, users therefore not well know the vacuum state at another moment. The devices can't auto-detect and adjust the vacuum state immediately. So the food in the devices may not be in the well-protected.

In order to overcome the disadvantage of the conventional food container, the inventor of the present invention provides an improved and adjustable vacuum food storage container to overcome the issue mentioned above.

SUMMARY

An object of the invention is to provide a food storage container having detect and adjust vacuum state functions, which can automatically detect the pressure inside the container and adjust to vacuum state immediately.

To achieve the above object, the invention is to provide a food storage container which comprise of a base, a U-shaped socket mounted on the base, and a cover covering the U-shaped socket. Wherein the upper cover comprises of an exhaust valve, and the base comprises of a vacuum controller, a pressure detective means, an out connector power means, a spare battery set, a power switch, and an integrated circuit board. The integrated circuit board drives the other constituents by wires; the pressure detective means is connected to the U-shaped socket for auto-detecting the accommodation pressure between the socket and the upper cover, and the vacuum controller is combined to the pressure detective means for keeping the accommodation pressure between the socket and the upper cover at a vacuum state at any moment.

A plate is disposed inside the U-shaped socket to provide a platform for placing food, and on the square barriers of the U-shaped socket are grooves set with seal washers to prevent air from leaking when the U-shaped socket and the upper cover are closed by junction elements. Furthermore, on the U-shaped socket surface is configured with a power guiding light.

Moreover, the vacuum controller comprises of a motor, an eccentric, a rock arm, a vacuum pump, a protective cover, a back pressure valve, pipes and clamping rings; wherein one end of the eccentric is connected to vacuum pump by the rock arm, and the other end is connected to the motor. The vacuum pump combined the back pressure valve by the pipe; and the clamping rings set on the connective parts between the pipes and the vacuum pump or the pipes and the back pressure valve. The motor, the eccentric, the rock arm and the vacuum pump constitute an air-removal means. The protective cover covers the air-removal means to protect the vacuum pump and the motor, to decrease the noise when the machine works, and to circulate the exhausted-air from the vacuum pump to cool the motor, the back pressure valve prevents the removed-air from reversing back.

In addition, the pressure detective means comprises of a pressure sensor, a filter, and pipes and clamping rings, wherein the filter connects to the pressure sensor on one side, and connects to the back pressure valve on the other side. Pipes are the connective elements. The filter is disposed on the plate of the U-shaped socket to prevent food residues from sucking into the air-removal means. The pressure sensor can auto-detect the pressure of the accommodation between the upper cover and the U-shaped socket, and actuate the integrated circuit board to drive the motor through the power switch to switch on or off the vacuum pump until the pressure of the accommodation was achieved a pre-determined. Wherein the pressure can be detected by the pressure sensor ranges from 0 to 60 Kpa (negative pressure).

Moreover, the out connector power means comprises of a DC contact, a magnetic loop and a transformer, wherein the DC contact was hoop by the magnetic loop to avoid electrostatic, and the transformer could be selectively inserted to the DC contact on one side and further connect to external power on the other side.

The spare battery set can be installed with several cells to supply power independently without any external power supplement.

Furthermore, the suction force of the vacuum pump can range from 0 to 50 Kpa, and preferably the pressure of the accommodation between the upper cover and the U-shaped socket is kept at about 35 Kpa.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded view the food storage container of the preferred embodiment according to the invention;

FIG. 2 is a perspective view of the food storage container of the preferred embodiment according to the invention;

FIG. 3 is a bottom view of the food storage container of the preferred embodiment according to the invention;

FIG. 4 is a top perspective view of the food storage container of the preferred embodiment according to the invention;

FIG. 5 is a perspective view of the vacuum controller of the preferred embodiment according to the invention;

FIG. 6 is a perspective view of the clipper of the second preferred embodiment according to the invention.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

With reference to FIG. 1 and FIG. 2, FIG. 1 and FIG. 2 are the exploded view and perspective view of the food storage container of the preferred embodiment according to the invention. As illustrated in the figures, the food storage container comprises a base 3, a U-Shaped socket 2 mounted on the base 3, and a transparent upper cover 1 covering the socket 2.

Moreover, the upper cover 1 can be combined with the U-Shaped socket 2 by a joint pivot 11 and a pivot socket 25, and the cover linking unit 131 of the switch 13 can be clipped laterally to the protruding part 26 of the U-Shaped socket 2 when the container 1 is closed. Additionally, an exhaust valve 12 is disposed on the upper cover 1 to discharge air.

A plate 22 is disposed inside the U-shaped socket 2 to provide a platform for placing food, and on the square barriers 23 of the U-shaped socket 2 are grooves 231 configured with seal washers 232 to prevent the air from leaking when the machine are closed. And, a power guiding light 24 is disposed on outer surface of the U-shaped socket 2, to display the machine work status.

Furthermore, the base 3 comprises of a vacuum controller 31, a pressure detective means 32, an out connector power 33, a spare battery set 34, a power switch 35, and an integrated circuit board 36, wherein the integrated circuit board 36 can connect and drive the other constituents by the wires 361.

With reference to FIG. 4 and FIG. 5, FIG. 4 is a top perspective view of the food storage container of the preferred embodiment according to the invention, and FIG. 5 is a perspective view of the vacuum controller of the preferred embodiment according to the invention. The vacuum controller 31 comprises of a motor 311, an eccentric 312, a rock arm 313, a vacuum pump 314, a protective cover 315, a back pressure valve 316, pipes 317, and clamping rings 318. Wherein one end of the eccentric 312 connects to the vacuum pump 314 by the rock arm 313, and the other end of the eccentric 312 connects to the motor 311. The vacuum pump 314 combined with the back pressure valve 316 by the pipe 317 and the clamping rings 318 disposed on the connective parts between the pipes 317 and the vacuum pump 314 or the pipes 317 and the back pressure valve 316. So the motor 311, the eccentric 312, the rock arm 313, and the vacuum pump 314 form an air-removal means. The protective cover 315 covers the air-removal means and protect the vacuum pump 314 and the motor 311, to decrease the noise when the machine works, and to circulate the exhausted-air from the vacuum pump 314 to cool the motor 311, furthermore the back pressure valve 316 preventing the removed-air from reversing back.

In addition, the pressure detective means 32 comprises of a pressure sensor 321, a filter 322, pipes 323 and clamping rings 324; wherein the filter 322 connects to the pressure sensor 321 on one side and connects to the back pressure valve 316 on the other side. The connective elements are the pipes 323. The clamping rings 318 are disposed between the pipes 323 and the filter 322 or the pipes 323 and pressure sensor 321. The filter 322 is disposed on the plate of the U-shaped socket 2 to prevent food residues from sucking into the air-removal means. The pressure sensor 321 can auto-detect the pressure of the accommodation between the upper cover 1 and the U-shaped socket 2, and actuate the integrated circuit board to drive the motor 311 through the power switch 35 to switch on or off the vacuum pump 314 until the pressure of the accommodation achieving to the pre-determined. Wherein the pressure can be detected by the pressure sensor ranges from 0 to 60 Kpa (negative pressure).

Moreover, the out connector power 33 comprises of a DC contact 331, a magnetic loop (not shown) and a transformer 37. Wherein the DC contact 331 is hoop by the magnetic loop to avoid electrostatic, and the transformer 37 could be selectively inserted to the DC contact 331 on one side and further connect to external power on the other side.

Referred to FIG. 3, it is a bottom view of the food storage container of the preferred embodiment according to the invention. The spare battery set 34 can be installed with several cells 38 to supply power independently without any external power supplement.

With reference to FIG. 6, it is a perspective view of the clipper of the second preferred embodiment according to the invention. As shows in FIG. 6, clippers 132 substituted for switch 13 are disposed on the upper cover 1 to clamp the U-shaped socket 2.

Furthermore, the suction force of the vacuum pump can range from 0 to 50 Kpa, and preferably the pressure of the accommodation between the upper cover and the U-shaped socket is kept at about 35 Kpa.

Various embodiments and changes could be made thereunto without departing from the broad spirit and scope of the invention. The above-described embodiment is intended to illustrate the present invention, not to limit the scope of the present invention.

The scope of the present invention is shown by the attached claims rather than the embodiment. Various modifications made within the meaning of an equivalent of the claims of the invention and within the claims are to be regarded to be in the scope of the present invention. 

1. an adjustable vacuum food storage container, comprising: a base; an U-shaped socket mounted on the base; and an upper cover covering the U-shaped socket, wherein a vacuum controller and a pressure detective means are disposed on the base, and an exhaust valve are further added on upper cover; the pressure detective means is connected to the U-shaped socket for auto-detecting the accommodation pressure between the U-shaped socket and the upper cover, and the vacuum controller associated with the pressure detective means for keeping the accommodation pressure at a vacuum state always.
 2. The adjustable vacuum food storage container of claim 1, wherein the vacuum controller further comprises an air-removal means, a protective cover covering the air-removal means, pipes and clamping rings.
 3. The adjustable vacuum food storage container of claim 2, wherein the vacuum controller further comprises a back pressure valve installed between the air-removal means and the pressure detective means to prevent the removed-air from reversing back.
 4. The adjustable vacuum food storage container of claim 2, wherein the air-removal means can comprise of a motor, an eccentric, a rock arm, and a vacuum pump.
 5. The adjustable vacuum food storage container of claim 1, wherein the pressure detective means can comprise of a pressure sensor, pipes and clamping rings.
 6. The adjustable vacuum food storage container of claim 5, wherein the pressure detective means further comprises of a filter set on the U-shaped socket and connected to the pressure sensor.
 7. The adjustable vacuum food storage container of claim 1, wherein the pressure of the accommodation between the upper cover and the U-shaped socket is kept at about 35 Kpa.
 8. The adjustable vacuum food storage container of claim 4, wherein the suction force of the vacuum pump ranges from 0 to 50 Kpa.
 9. The adjustable vacuum food storage container of claim 5, wherein the pressure detected by the pressure sensor ranges from 0 to 60 Kpa (negative pressure).
 10. The adjustable vacuum food storage container of claim 1, wherein the base further comprises of an out connector power means, a spare battery set, and a power switch.
 11. The adjustable vacuum food storage container of claim 10, wherein the out connector power means can comprise of a DC contact, a magnetic loop and a transformer, the DC contact hoop by the magnetic loop, the transformer insert to the DC contact and further connected to external power.
 12. The adjustable vacuum food storage container of claim 1, wherein a switch or a clipper of the upper cover can be clipped laterally to a protrudent part of the U-Shaped socket. 